An UNBELIEVABLE fault in Dave's Alesis M1 Active 520USB powered studio monitor speaker.Can you discover the fault before Dave does?This was supposed to be a boring trivial repair of a power LED, but it turned into something much more interesting.

I have only ever seen this once myself, and it was with a single colour blue led when they first came out......inspecting the led under a microscope you could see a very small arc on one of the bond wires as you cranked up the supply.....it was very repeatable and you would swear it was designed to work that way.

It would be interesting to put this led in some curve tracer (signal generator + resistor + oscilloscope in XY mode), to see the voltage curve in low current (0-20mA) range. There could be some funny weird effects visible on this curve.

We have had issues with blue LEDs in a sensor setup (a device to measure the color of a liquid), they degraded much faster than other colors. We needed some serious compensation for it in software. The other LEDs would easily outlast the actual device and still be in spec. The blue one degraded by more than 40% in 10 years, while the others were less than 5%. It wasn't temperature related, the boards were kept at room temperature. They also ran at below maximum current.

I had an IR LED in an wireless headset (those old ones with IR transmission) to fail in a blinking way. For quite some time it did an about 1 second on, 1 second off. The good think was that those 880 nm LEDs are still a little visible.

I got a failure in a lab PSU screen backlight, which suddenly started to flicker. When you powered it on it stayed ON for a while and then it started flickering at a quite high frequency. The issue was some a bad contact inside the LED itself. When you applied power to it it turned on, but after several seconds it reached a certain temperature where thermal expansion interrupted the bad contact, the LED then turned off, cooled down, the contact engaged again and the cycle repeated. I had some fun experimenting with it, seeing how it changed frequency with temperature. If you submerged it in ice cold water it stayed on indefinitely, and at about 40ºC it stopped working.

Wonder what the standby power consumption is on this. If its properly applying standby to the amplifier IC its probably not too bad, but still terrible compared to SMPS + Class D.Couldn't find anything in their manual for specifications.

Reminds me of the night light LEDs that big clive looked at, where the transistor shunts out the LED during daylight. Very simple and cheap design.

Wonder what the standby power consumption is on this. If its properly applying standby to the amplifier IC its probably not too bad, but still terrible compared to SMPS + Class D.Couldn't find anything in their manual for specifications.

I should measure it, but I don't have power meter at the office.It's likely quite poor.

Wonder what the standby power consumption is on this. If its properly applying standby to the amplifier IC its probably not too bad, but still terrible compared to SMPS + Class D.Couldn't find anything in their manual for specifications.

I should measure it, but I don't have power meter at the office.It's likely quite poor.

Certainly it is an interesting phenomenon.It may be caused by dendritic growth within the moulding compound surrounding the leadouts of the Blue LEDs.If the two leadout wires are close together, and there is some moisture content, or uncured resin or activator within the moulding, then the potential gradient may be sufficient, over a long period with applied voltage bias, to cause dendrites to form within the moulding by an electrochemical migration process.Eventually, these dendrites may result in a resistive conductive channel across the LED, which will divert the current that was intended for the LED. When an increased current is supplied, this blows away part of the dendrite (like a fuse blowing), allowing the LED to work again. However, when the current is reduced, the dendrites grow back again so that the LED becomes intermittent and then stops working.Another mechanism is the growth of tin whiskers. However, these are much smaller diameter, and will probably cause a direct short, which would have been detected by your multimeter tests. Also I believe that the tin whiskers would grow regardless of the applied voltage bias.The dendrites may be visible (assuming a transparent moulding) with your microscope, as a dark channel between the leadout frame.https://nepp.nasa.gov/whisker/background/index.htmHope this helps